Advanced PCI express board assembly

ABSTRACT

An advanced PCI Express board assembly is intended for efficiently placing more electronic components or modules having a large height (up to 8.57 mm) in comparison with traditional PCI Express add-in boards. This assembly comprises two PCBs connected together. The first one has the minimum possible sizes. This PCB includes a PCI Express male edge connector and is intended to be plugged in to motherboard female PCI Express connector. The second PCB is parallel to first one and is located in the middle of the space (slot) defined for one add-in PCI Express board. This position makes possible to place high electronic components or modules on the both sides (top and bottom) of the second PCB.

CROSS-REFERENCE TO RELATED APPLICATION

This is the first application filed for the present invention.

TECHNICAL FIELD

The present invention relates to the field of high-performance computertechnology and, in particular, to add-in PCI Express Boards intended fora compact arrangement of large numbers of high electronic components ormodules.

BACKGROUND

Today there is a class of PCI Express boards that are dedicated for themultichannel wireless communication market. The main feature of theseboards is that these boards use different wireless modules or blockslocated on the PCB surface. Most of these wireless modules areimplemented in a MiniPCI Express or M.2 form factor.

The wireless module itself or wireless modules in MiniPCI Express or M.2form factor are significantly higher than standard electronic componentsthat can be placed on the PCI Express board PCB.

The PCI Express add-in board specification limits the height of thecomponents that can be placed on each side of the PCB. The maximumheight of components on the primary component side (top side) of a PCIExpress add-in card can't exceed 14.47 mm, and the maximum height ofcomponents on the bottom side (also referred to as the soldering side)of the PCI Express add-in card can't exceed 2.67 mm (according to thePCI Express Specification). These requirements essentially limit thepossibility of using the bottom side of the PCI Express board for highelectronic components or wireless modules placement.

The development road map of modern personal computers (motherboards) ismoving towards reducing the quantity of PCI Express sockets forconnecting add-in PCI Express boards. The most popular motherboards haveone or two ×16 PCI Express connectors. As the result the number ofadd-in PCI Express boards that can be connected to the motherboarddecreases.

Therefore, efficiency of PCI Express board surface utilization andincreasing the number of electronic components or electronic modules onthe PCI Express board are becoming top priorities.

The well-known way to increase the number of electronic components orelectronic modules on the PCI Express add-in board is using so-calleddaughter boards that mechanically and electrically are connected to thePCI Express add-in board. These daughter boards are located in parallelto the add-in PCI Express boards and mount on the top side of them.

US Pat. Application 20140365714 (P. Sweere, et al) represented anadditional daughter-card (PCB), on which additional electroniccomponents are located. Said daughter PCB is located in parallel to theadd-in PCI Express board. The total height of the components that arelocated on the top surface of the PCI Express add-in board together withdaughter board components and the thickness of a printed board of saiddaughter board can't exceed the value of 14.47 mm that is defined by PCIExpress Specification. The daughter board is connected to main add-inPCI Express board via “a flash daughter-card connector”.

U.S. Pat. No. 8,639,863 (P. Kanapathippillai, et al.) proposed to usemultiple daughter boards located on the top side of the PCI Expressadd-in board in two layers. The total height of the components from thetop side surface of the PCI Express add-in board including the daughterboard components and daughter board PCB thickness can't exceed the valueof 14.47 mm. Therefore, the height of components located between the topside surface of the PCI Express add-in board and the bottom side surfaceof the daughter board and height of the components on the top sidesurface of the daughter board are significantly limited.

Solutions with daughter boards have four main disadvantages. First, airflow between daughter boards and PCI Express add-in board is limited,and the placement of electrical components that can generate significantamounts of heat between the daughter board and PCI Express add-in board(top side) is not possible.

Second, the traditional PCI Express add-in board with a daughter boardon the top side can't utilize the 2.67 mm space on the bottom side ofthe PCI Express add-in board for high electronic components or modulesplacement (like transformers, relays, capacitors etc.).

Third disadvantage is that by using any additional daughter boards themaximum height of electronic components that can be located on the topside of the PCI Express board is reduced by the value equal to thedaughter board thickness. And the resulting maximum height is divided bydaughter board. That makes it practically impossible to installelectronic components with a height of more than 4 mm.

Fourth disadvantage is that all known standard solutions with daughterboards cannot be used for the placement of multiple replaceable modules(for example wireless modules in MiniPCI Express or M.2 form factor thatcan have height more than 6 mm). Even if the modules are placed betweenthe daughter board and PCI Express add-in board, they are then notaccessible for replacement.

BRIEF SUMMARY OF THE INVENTION

The first aspect of the present invention consists in that the offeredAdvanced PCI Express board assembly allows significantly increasing thenumber of high electronic components or modules of height up to 8.57 mmcompared to traditional PCI Express add-in boards.

The next aspect of the present invention consists in that the proposedassembly allows placing large electronic components or modules on theboth sides of the PCB, that is located in the middle of the maximumspace that PCI Express specification reserves for one-slot PCI Expressadd-in boards.

The third aspect of the present invention consists in that the offeredassembly increases an efficiency of air flow cooling by allowing highcomponents or modules to be placed on both sides (top and bottom) of thePCB.

The fourth aspect of the present invention consists in that saidassembly provides a wide opportunity of using exchangeable male edge PCIExpress connectors corresponding to ×1, ×2, ×4, ×8 or ×16 lanes. Thisarchitecture allows plugging the proposed PCI Express assembly intodifferent motherboard female PCI Express connectors.

The next aspect consists in that there is no restriction on thethickness of the PCB on which high components are placed, because thisPCB is not intended to be plugged into a PCI Express female connector.The thickness of this PCB can be increased to prevent PCB twistingbecause of the PCB length and heavy component installation.

BRIEF DESCRIPTION OF THE DRAWING

FIGS. 1A-1B show the proposed Advanced PCI Express board assemblyinserted in to a motherboard PCI Express female connector; FIG. 1Arepresents a top side view of said assembly; FIG. 1B represents asectional view executed along line A-A of said advanced PCI Expressboard assembly.

FIGS. 2A-2B show the proposed Advanced PCI Express board assembly; FIG.2A represents a top side view of said assembly; FIG. 2B represents asectional view executed along line A-A of said advanced PCI Expressboard assembly shown on FIG. 2A.

FIG. 3A shows a cross view of a traditional add-in PCI Express boardwith restricted height of components based on the PCI ExpressSpecification.

FIG. 3B shows a cross view of the proposed Advanced PCI Express boardassembly with restricted height of components based on the PCI ExpressSpecification.

FIG. 4 shows the proposed Advanced PCI Express board assembly togetherwith components installed on the both sides of the Main board.

FIGS. 5A-5C show examples of the Adapter board together with means formechanical and electrical connection to the Main board.

FIG. 6 shows an example of the Main board together with means formechanical and electrical connection to the Adapter board.

FIG. 7 shows a diagram of electrical signal connections between the Mainboard and the Adapter board.

DETAIL DESCRIPTION OF THE INVENTION

FIG. 1A represents a view of the proposed Advanced PCI Express boardassembly 1 inserted into a female PCI Express connector 3 that islocated on a computer system board 2, for example, a motherboard. Thefemale PCI express connector 3 has a receiving portion 40 defining acenterline that extends in a longitudinal direction 41. The proposedAdvanced PCI Express board assembly (FIG. 1B) consists of the Main board6, the Adapter board 5 and means for electrical and mechanicalconnection 4 of said Main board 6 and Adapter board 5. One or moreconnectors can be used for electrical connection of said Adapter board 5and Main board 6. Spacers can be used for additional mechanicalstabilization. The spacers can be fixed on the Adapter board 5 and/orMain board 6 via solder, glue, screws etc. The connection between saidAdapter board and said Main board can be permanent when there is nopossibility to disconnect both boards after assembly or, on thecontrary, both boards can be disconnected after assembly.

In general, the PCI Express board assembly 1 is compliant with the PCIExpress Specification and intended for use in a computerized system. Thecomputerized system can include a motherboard with at least one PCIExpress slot and a female PCI Express connector mounted on themotherboard inside the PCI express slot. The assembly can include anAdapter board 5, a Main board 6, and connectors for attaching andelectrically connecting the Adapter board 5 and Main board 6. Theconnectors can be positioned between the Adapter board 5 and Main board6. The connectors (e.g. stackable connectors, mechanical spacers,screws, clamps, spacers and/or any combinations of such connectors) canmechanically attach and keep the Adapter board 5 and Main board 6 inparallel and at a predetermined distance apart in a lateral direction42. For example, the Adapter board 5 and Main board 5 may be maintainedat a predetermined distance of about 4.3 mm in cases where the thicknessof the Main board 6 is about 1.57 mm (e.g. as shown in FIG. 3B). Thepredetermined distance can be selected based on the desired applicationof the PCI express board assembly 1. The connectors also include signalconnectors that provide an electrical connection between the Main Board6 and the motherboard 2 via the Adapter board 5. The signal connectorsenable transmission of all necessary electrical communication signalsbetween the Main board 6 and the motherboard 2, including signals fromthe PCI Express upstream port. The signal connectors can include one ormore connectors, traces or wires. In some cases, the signal connectorsmay also be used to mechanically attach the adapter board 5 and mainboard 6.

The Adapter Board 5 includes a male edge PCI Express connector. The maleedge PCI Express connector can be used to mount the Adapter Board 5 tothe female PCI express connector 3 on the motherboard 2. The Main board6 includes a PCI Express interface circuit including a PCI expressupstream port. The PCI express upstream port can be electrically coupleddirectly to the male edge PCI Express connector on the Adapter Board 5.

In the proposed assembly, the Main board 6 and Adapter board 5 canoccupy a region that complies with the PCI Express specification for aone slot add-in PCI Express board (i.e. the occupied region is notgreater than the maximum space for a one slot add-in PCI Express board).The Adapter board 5 and Main board 6 can be retained at a predetermineddistance chosen to provide an approximately equal space for componentsthat can be installed on the top (or component) side 44 and bottom (orsoldering) side 45 of the Main board 6 (e.g. as shown in FIG. 3B). Otherpredetermined distances may be chosen depending on the application ofthe PCI express board assembly 1.

FIG. 2A represents a top side view of the Advanced PCI Express boardassembly with the male edge PCI Express connector 7 located on theAdapter board 5. Said male edge PCI Express connector 7 is intended forconnecting to the PCI Express interface connector 3 of the motherboard2. FIG. 2B shows a sectional view of the Advanced PCI Express boardassembly shown in FIG. 2A along line A-A shown in FIG. 2A.

FIG. 3A shows a cross-sectional view of a traditional PCI Express board8 inserted into a female PCI Express connector 3 that is located on themotherboard 2. FIG. 3A shows the height restriction for components thatare located on the top 44 and bottom sides 45 of the PCB 8. The value a1shows the maximum height of components on the bottom side 45 of the PCBas defined by PCI Express specification, and it is equal to 2.67 mm inFIG. 3A. The value a2 shows the maximum height of components on the topside 44 of the PCB as defined by PCI Express specification, and it isequal to 14.47 mm. The value a3 represents the size of the spacereserved for a one-slot PCI Express add-in board by the PCI Expressspecification, and it is equal to 18.71 mm. The female PCI expressconnector 3 has a top side upper surface 43 that extends in the lateraldirection 42 from a first top side edge 46 adjacent the receivingportion 40 to a second top side edge 47 over a first distance.

As mentioned, the Adapter board 5 and Main board 6 can be maintained ata predetermined distance apart in the lateral direction 42. As shown inFIG. 3B, the main board 6 can be offset from the receiving portion 40 inthe lateral direction 42 by a second distance that is greater than thefirst distance over which the top side upper surface 43 of the femalePCI express connector 3 extends.

FIG. 3B shows a cross-sectional view of the proposed Advanced PCIExpress board assembly of FIG. 1B. A value a4 shows the maximum heightof components on the top side 44 of the Main board 6 when the Main board6 is located in the middle of the space that is reserved for one-slotPCI Express add-in board by the PCI Express specification. A value a5shows the maximum height of components on the bottom side 45 of the Mainboard 6. The values of a5 and a4 are equal to 8.57 mm (in case thethickness of the Main board 6 is 1.57 mm). Most electronic componentslike transformers, capacitors, ICs with heat sinks, relays, modules etc.have height less than 8.57 mm but higher than 4 mm. These components canbe assembled on the top 44 and bottom 45 sides of the Main board 6without violation of PCI Express specification. In actual practice saidvalues a4=d±b and a5=d−(±b), where d=8.57 mm and b is several timessmaller than d. Where said value “b” is chosen based on the actual sizeof used components and structural elements.

In some examples, the Main Board 6 and the Adapter Board 5 can berigidly connected by the mechanical connectors as described below. TheMain Board 6 can be secured approximately in the middle of a PCI Expressslot which corresponds to the maximum a3 space defined by PCI Expressspecification for a one slot add-in PCI Express board.

In some cases, the mechanical connectors between the Main Board 6 andthe Adapter board 5 can include fixed connectors, e.g. attached to theMain Board 6 and/or Adapter board 5 by glue or solder. In other cases,the Main board 6 and Adapter board 5 may be detachably attached. Forexample, the Main board 6 and Adapter board 5 may be detachably attachedusing one or more of a stackable connector, a mechanical spacer, ascrew, a clamp, a spacer and/or any combinations of such connectors,spacers, screws, clamps etc.

FIG. 4 shows a top view of the proposed Advanced PCI Express boardassembly together with components 9 assembled on both sides (top 44 andbottom 45) of the Main board 6. The area of the Adapter board 5 has tobe as small as possible to maximize efficiency in the placement of thehigh components 9. In FIG. 4, the Adapter board 5 has said male edge PCIExpress connector 7 (FIG. 2A) and means for electrical and mechanicalconnection 4 to Main board 6. Values a4 and a5 are shown on the FIG. 4.

In FIG. 4 a PCI Express bracket 10 is shown that is installed on theMain board 6. The PCI Express bracket 10 can be mounted on the Mainboard 6 via tabs located in the middle of said bracket. PCI Expressbracket can be mounted on the IO connectors located on the front edge ofthe Main board 6 as well (not shown).

The assembly can include a bracket 10 fastened to one or both of theMain Board 6 and the Adapter Board 5. The bracket 10 can be used formechanically stabilizing the assembly inside the PCI Express slot. Insome examples, the bracket 10 can be fastened to the Main Board 6directly, e.g. using one or more bracket tabs. In some examples, thebracket 10 can be fastened to one or more edge mounted input/outputconnectors located on the front edge of the Main Board 6.

FIGS. 5A-5C show examples of said Adapter board 5 for different sizes ofthe motherboard female PCI Express connectors 7. The PCI Expressinterface can be one lane (×1), 2 lanes (×2), 4 lanes (×4), 8 lanes(×8), or 16 lanes (×16) wide. The PCI Express connector has differentlength depending on the numbers of supporting lanes. Each PCI Expressconnector is divided into 2 sections: a front section 14 that includeslow speed control signals and power, and communication sections 13, 17,18 that includes high-speed differential communication signals.

FIG. 5A shows the example of the Adapter board 5 having ×1 male edge PCIExpress connector. The communication section 13 is very small andincludes in this case only 3 differential signal pairs. FIG. 5B showsthe example of the Adapter board 5 having ×8 male edge PCI Expressconnector. The communication section 17 in this case is longer andincludes 14 additional differential signal pairs compared to ×1connector. FIG. 5C shows the example of Adapter board 5 having ×16 maleedge PCI Express connector. The communication section 18 in this case islonger than in ×8 PCI Express connector and includes 30 additionaldifferential signal pairs compared to ×1 connector. In all said casesthe front sections 14 are exactly the same mechanically andelectrically.

The FIG. 5A shows an example of means for electrical and mechanicalconnection of the Adapter board 5 (×1 PCI Express connector) and theMain board 6 (FIG. 6) located on the Adapter board 5. Said means includetwo connectors 12, 11 and mounting hole 15. The size of the connector 12and 11 is chosen based on the number of signals between Adapter board 5and Main board 6 (FIG. 6). The front connector 12 is used for theconnection low speed signals and power signals from front section of thePCI Express connector 14. The connector 11 is used for the connection ofhigh speed signals from the communication section 13 of the PCI Expressconnector.

The FIG. 5B shows an example of means for electrical and mechanicalconnection of the Adapter board 5 (×8 PCI Express connector) and theMain board 6 (FIG. 6) located on the Adapter board 5. Said means includetwo connectors 12, 16 and the mounting hole 15. Connector 16 in thiscase has more pins compared to the similar connector 11 on FIG. 5A.

The FIG. 5C shows an example of means for electrical and mechanicalconnection of the Adapter board 5 (×16 PCI Express connector) and theMain board 6 (FIG. 6) located on the Adapter board 5. Said means includetwo connectors 12, 19 and mounting hole 15. Said connector 19 in thiscase includes all signals from the ×16 PCI express connector section 18.The connector 19 can be split into multiple smaller connectors (notshown).

The FIG. 6 shows the bottom side 45 of the Main board 6 where means forconnection of Adapter board 5 (not shown) and Main board 6 are placed.These means include two connectors 20, 21 and a spacer 22.

The height of the spacer 22 and type of the connectors 20, 21, 12, 19,16, 11 that are located on the Adapter board 5 and Main board 6 definethe space between Adapter board 5 and Main board 6 and is equal to t±c,where t=4.33 mm and c is several times smaller than t. Where said value“c” is chosen based on the actual size of components and structuralelements that are located on the Main board 6. This distance places Mainboard 6 in the middle of the space reserved for one-slot PCI Expressadd-in boards by PCI Express specification.

When the Main board 6 and the Adapter board 5 are assembled together thefront connector 20 on the Main board 6 shown in FIG. 6 will mate toconnector 12 on the Adapter board 5 (FIG. 5A-5C). The high speed signalconnector 21 will mate to said high speed signal connector on theAdapter board that supports the same number of lanes as the Main board6. For example, if Main board 6 supports 16 lanes, then any Adapterboard can be connected to said Main board, and the connector 21 willmate with one of connectors 13, 17 or 18 (FIGS. 5A-5C). In case whensaid Main board supports one lane PCI Express interface then onlyAdapter board 5 (FIG. 5A) that has ×1 PCI Express connector can beconnected to the Main board 6, and the connector 21 will mate only withconnector 13 (FIG. 5A).

The spacer 22 can be soldered, glued or fix by screw on the bottom sideof the Main board 6. In this case when the Main board 6 is assembledwith the Adapter board 5 together they can be additionally (in additionto the mating connectors) mechanically fastened together by a screw thatcan be tighten via mounting hole 15 (FIGS. 5A-5C) to said spacer 22(FIG. 6).

The location of the spacer 22 (FIG. 6) and the mounting hole 15 (FIGS.5A-5C) is chosen in the place where are no signals on the Adapter board5 (FIGS. 5A-5C) and PCBs of said Boards have a space for the hole. Thisarea is located close to the PCB cut-out of said male edge PCI Expressconnector.

At least one of the mechanical connectors, such as a spacer, can bealigned with a cut-out on the male edge PCI Express connector. Thisspacer may be located on a line that passes approximately via the centerline of the mechanical key cut-out on the PCI Express male edgeconnector of the Adapter Board 5. The mechanical connector can befastened on the Adapter Board 5 and said Main Board 6 using a fastenersuch as glue, a screw, or a clamp.

FIG. 7 shows the diagram of an electrical connection between the Mainboard 6 and the Adapter board 5 and the Motherboard female PCI Expressconnector 3 located on the motherboard 2 (FIG. 1A). A male edge PCIExpress connector 7 is located on the Adapter board 5 and is intended tobe plugged in to the motherboard female PCI Express connector 3. A codegenerator 26 creates the code that defines the size of the male edge PCIExpress connector 7 that is located on the Adapter board 5 and this codeis defined during Adapter board 5 production. The Adapter board 5 hasmeans for electrical and mechanical connection 23. These means 23 areintended for connection to the means for electrical and mechanicalconnection 24 located on the Main board 6 when both Adapter and Mainboards assembled together. A PCI Express interface circuit 25 is locatedon the Main board 6. The PCI Express interface circuit 25 can beimplemented for example as a PCI Express switch or a PCI Express bridge.The upstream PCI Express port of PCI Express circuit 25 connects to PCIExpress root complex (not shown) located on the motherboard board 2 viabuses 32, 33, 28, 27, means for electrical and mechanical connection 23,24 and PCI Express connectors 7, 3.

The PCI Express upstream port of the PCI Express interface circuit cansupport 1 lane, 2 lane, 4 lane, 8 lane, or 16 lane connections. In somecases, the electrical signal connectors between the main board 6 and theadapter board 5 may include signal connectors for all supported PCIExpress upstream port lanes. In other cases, the electrical signalconnectors may include a reduced number of signal connectors for areduced number of upstream port lanes.

In various examples, the male edge PCI Express connector of the AdapterBoard 5 can support 1 lane, 2 lane, 4 lane, 8 lane, or 16 laneconnections. The Adapter board 5 can also include an electrical circuitfor generating code based on the number of PCI express lanes supportedby the male edge PCI Express connector of that Adapter board 5. The codegenerating electrical circuit can be connected to the PCI Expressinterface circuit on the main board 6 via the electrical signalconnectors. The code generating electrical circuit can configure the PCIExpress interface circuit and the PCI Express upstream port on the mainboard 6 to operate in accordance with the number of lanes supported bythe Adapter board 5. The code generating electrical circuit canconfigure the PCI Express interface circuit and the PCI Express upstreamport to operate using a reduced number of lanes.

The code from the code generator 26 via signals 29, 30, 31 connects tothe PCI Express interface circuit 25 and setup the PCI Express interfacecircuit 25 operation based on the lane number that the Adapter board 5supports. This code allows changing operations of the PCI Expresscircuit 25, which includes the upstream port, in cases when the numberof lanes that connect to the motherboard PCI Express root complex (notshown) is decreased by the Adapter board 5.

We claim:
 1. A PCI express board assembly for mounting to a female PCIexpress connector provided on a motherboard, the female PCI expressconnector having a receiving portion defining a centerline extending ina longitudinal direction, and the motherboard defining a motherboardplane, the PCI express board assembly comprising: a main boardcomprising a PCI express interface circuit configured to supportcommunication over a plurality of main board PCI express lanes, the mainboard defining a main board plane extending along a longitudinal mainboard centerline; an adapter board comprising a male PCI expressconnector, wherein the male PCI express connector is receivable in thereceiving portion of the female PCI express connector to secure theadapter board to the motherboard, the adapter board defining an adapterboard plane, and the adapter board comprising a code generation circuitthat is configured to deactivate some of the main board PCI expresslanes supported by the PCI express interface circuit while maintainingat least one main board PCI express lane activated; and a connectorsection comprising a plurality of connectors attaching the main board tothe adapter board; wherein the main board plane is parallel to theadapter board plane, and the main board plane and the adapter boardplane are laterally offset from each other, the plurality of connectorscomprising: (i) a plurality of signal connectors for electricallycoupling the main board to the adapter board, and (ii) at least onemechanical connector; wherein when the adapter board is secured to themotherboard with the male PCI express connector received in the femalePCI express connector: (i) the adapter board plane is aligned with thecenterline of the female PCI express connector and perpendicular to themotherboard plane; and (ii) the main board plane is offset from thereceiving portion of the female PCI express connector in a lateraldirection and the main board plane is perpendicular to the motherboardplane.
 2. The assembly of claim 1, wherein the PCI express interfacecircuit comprises one of a PCI express switch and a PCI express bridge.3. The assembly of claim 1, wherein the main board plane is offset fromthe centerline of the female PCI express connector in a lateraldirection by about 5 mm-7 mm.
 4. The assembly of claim 1, wherein: thereceiving portion has a lateral receiving portion width; and the mainboard comprises a printed circuit board having a lateral thicknessgreater than the lateral receiving portion width.
 5. The assembly ofclaim 1, wherein the main board has a thickness that is different from athickness of the adapter board.
 6. The assembly of claim 1, wherein: thefemale PCI express connector has a top side upper surface that extendsin the lateral direction from a first top side edge adjacent thereceiving portion to a second top side edge over a first distance, thetop side upper surface defining a maximum female connector height; themain board plane is offset in the lateral direction from the receivingportion of the female PCI express connector over a second distance; andthe second distance is greater than the first distance.
 7. The assemblyof claim 1, further comprising a bracket mechanically coupled to themain board, the bracket extending in a direction parallel to the mainboard plane.
 8. The assembly of claim 7, wherein the bracket has abracket centerline extending in the direction parallel to the main boardplane and the main board plane is aligned with the bracket centerline.9. The assembly of claim 1, wherein the adapter board is detachablyattached to the main board.
 10. The assembly of claim 1, wherein: theadapter board is configured to support communication over at least oneadapter board PCI express lane that includes fewer PCI express lanesthan the plurality of main board PCI express lanes.
 11. The assembly ofclaim 10, wherein: the code generation circuit is configured to definecode to change operation of the main board to support communication overa reduced number of main board PCI express lanes corresponding to the atleast one adapter board PCI express lane.
 12. The assembly of claim 1,wherein when the adapter board is mounted to the female PCI expressconnector, a height of the main board in a direction perpendicular tothe motherboard plane is greater than a height of the adapter board inthe direction perpendicular to the motherboard plane.
 13. The assemblyof claim 1, further comprising a spacer positioned between the mainboard and the adapter board; wherein: the male PCI express connector hasa cut-out section; and the spacer is aligned with the cut-out section.14. The assembly of claim 1, wherein: the female PCI express connectorhas a top side upper surface that extends in the lateral direction froma first top side edge adjacent the receiving portion to a second topside edge over a first distance; the adapter board has an upper edgedefining a maximum adapter board height; and the connector section ispositioned above the top side upper surface and extends between the topside upper surface and the maximum adapter board height.
 15. Theassembly of claim 1, wherein the main board has a top surface and abottom surface, wherein the main board comprises a first element mountedon the top surface having a height greater than 6 mm and a secondelement mounted on the bottom surface having a height greater than 6 mm.16. A PCI express board assembly for mounting to a female PCI expressconnector provided on a motherboard, the PCI express board assemblycomprising: a main board comprising a PCI express interface circuitconfigured to support communication over a plurality of main board PCIexpress lanes; an adapter board configured to support communication overat least one adapter board PCI express lane, the adapter boardcomprising a code generation circuit and a male PCI express connector,wherein the male PCI express connector is securable to the female PCIexpress connector, and wherein the at least one adapter board PCIexpress lane includes fewer PCI express lanes than the plurality of mainboard PCI express lanes; and a plurality of connectors attaching themain board to the adapter board, the plurality of connectors comprising:(i) a plurality of signal connectors for electrically coupling the mainboard to the adapter board, and (ii) at least one mechanical connector;wherein the code generation circuit is configured to deactivate some ofthe main board PCI express lanes supported by the PCI express interfacecircuit while maintaining at least one main board PCI express laneactivated to change operation of the main board to support communicationover main board PCI express lanes corresponding to the at least oneadapter board PCI express lane.
 17. The PCI express board assembly ofclaim 16, wherein the adapter board is detachable from the main board.18. The PCI express board assembly of claim 16, wherein the code definedby the code generation circuit is predefined during production.
 19. APCI express board assembly for mounting to a female PCI expressconnector provided in a PCI express reserved space on a motherboard, themotherboard defining a motherboard plane, and the female PCI expressconnector having a receiving portion extending in a longitudinaldirection parallel to the motherboard plane, and the reserved spacehaving a reserved space centerline extending in the longitudinaldirection, the PCI express board assembly comprising: a main boardcomprising a PCI express interface circuit configured to supportcommunication over a plurality of main board PCI express lanes, the mainboard defining a main board plane extending along a longitudinal mainboard centerline; an adapter board comprising a male PCI expressconnector that is receivable in the receiving portion and secureable tothe female PCI express connector, the adapter board comprising a codegeneration circuit that is configured to deactivate some of the mainboard PCI express lanes supported by the PCI express interface circuitwhile maintaining at least one main board PCI express lane activated;and a plurality of connectors for attaching the main board to theadapter board, the plurality of connectors comprising: (i) a pluralityof signal connectors for electrically coupling the main board to theadapter board, and (ii) at least one mechanical connector; wherein whenthe adapter board is secured to the female PCI express connector withthe male PCI express connector received in the female PCI expressconnector, the main board plane is perpendicular to the motherboardplane and the main board plane is aligned with the reserved spacecenterline.